RU2314640C1 - Client station for satellite communications - Google Patents

Abstract

FIELD: radio-electronic communication systems using radio-radiation during placement of station in ground-based mobile object, possible use as client station of satellite communication system with multi-station access with code division of channels (CDMA).

SUBSTANCE: in accordance to the invention, introduced to client station are band filter, broadband signal radio-modem block, controller of unified interfaces, block for controlling provision of channels on request, station control panel, block of client interfaces, radiation control block, block for check "self-oriented" operation of station, antenna control system, block for line input with lines connected to it for outputting (receiving) digital channels through standard connection, lines for outputting (receiving) channels through RS-232 connection and lines for outputting (receiving) channels of automatic telephone exchange.

EFFECT: increased interference resistance and traffic capacity of station, ensured flexibility and dynamicity of communication in networks of multi-station access with synchronous method of code division of channels in the mode of providing channels on request.

5 cl, 4 dwg

Description

The invention relates to electronic communication systems using radio emission when placing a station in a land mobile object and can be used as a subscriber station satellite communication system with multiple access with code division multiplexing (CDMA).

Subscriber satellite communication stations are known that include an antenna system, a rotary support device, a device for separating transmission and reception paths, a low-noise amplifier, frequency conversion devices for the receiving and transmitting paths, intermediate frequency amplifiers, a power amplifier, a block of modulator demodulators and a terminal channelization equipment [1, 2].

Known stations operate in a frequency division multiple access (FDMA) system in which a communication network using the full power of the repeater transmitter requires the allocation of a significant frequency resource due to the need to use uneven frequency arrangements in the repeater to combat combinational interference arising from nonlinearity. The combinational noise in the repeater can be significantly reduced by choosing a linear portion of the amplitude characteristic of the repeater, which leads to a decrease in the transmitter power of the repeater by 3-5 dB. At the same time, network bandwidth will decrease by two to three times.

Implementation of the principle of operation of stations with the provision of channels on demand (FCT) in the FDMA network leads to a significant complication of the stations.

In general, the FDMA system and, accordingly, stations built on this principle have low noise immunity, reduced bandwidth and flexibility of communication.

Of the known satellite communication subscriber stations, the closest in technical essence is the subscriber station, the structural diagram of which is given in [3].

A well-known satellite communication subscriber station (Fig. 15.1, p. 419) contains an antenna system, antenna guidance system, duplexer, low-noise amplifier, receive frequency converter, demodulator, modulator, transmit frequency converter, power amplifier, channel-forming equipment and a control processor.

Most satellite communication subscriber stations, including the prototype station, having the indicated composition and constructed according to the given structure, use frequency channel separation and have limited bandwidth capabilities due to low information transfer rates. The noise immunity from intentional and accidental interference of the radio channel of such stations is also low. The possibilities for organizing communication in the FDMA network with PCT are significantly limited.

This leads to a limitation of their use in modern satellite communications systems.

The aim of the present invention is to increase the noise immunity and bandwidth of the station, providing flexibility and efficiency of communication in multi-station access networks with a synchronous code division multiple access channel on demand mode constructed using the proposed satellite subscriber stations providing various types of terminal equipment.

This goal is achieved by the fact that in the subscriber satellite communication station containing an antenna, the input of which is connected to the control output of the slewing rotary device, a low-noise amplifier and a radio receiver are connected in series, a radio transmitter unit and a power amplifier, the output of which is connected to the antenna input, are connected in series a filter that protects the input of the reception path from the microwave signals of its transmitter, the radio modem unit of broadband signals (SHPS), the controller p unified interface, on-demand channel controller (PCT) unit, station control panel, station self-test station, radiation control unit, antenna control system, subscriber interface unit, line input unit with lines connected to it for delivery ( receiving) digital channels at a standard interface, lines for issuing (receiving) channels at the RS-232 interface and lines for issuing (receiving) channels of automatic telephone communications, the antenna output through a bandpass filter connected to the input low noise amplifier, the output of the radio receiver is connected to the input of the broadband signal modem unit, the inputs and outputs of which are connected to the first inputs and outputs of the unified interface controller, the second inputs and outputs of which are connected to the first inputs and outputs of the PCT controller by the high-speed RS-485 interface, the second inputs - the outputs of which at the RS-232 interface are connected to the inputs and outputs of the station control panel, the third inputs and outputs of the FCT controller unit are connected to the third inputs and outputs of the unified interface controller the fourth inputs and outputs of which are connected to the first inputs and outputs of the station operation check unit, the second inputs and outputs of which are connected to the fourth inputs and outputs of the FCT controller, the fifth inputs and outputs of which are connected via the parallel port to the first inputs and outputs subscriber interface unit, the second inputs and outputs of which at the TTL CAN interface are connected to the sixth inputs and outputs of the FCT controller unit, the third inputs and outputs of digital channels are connected to the standard interface of the subscriber unit the first station inputs and outputs of the line input unit, the second station inputs and outputs of which at the RS-232 interface are connected to the fourth inputs and outputs of the subscriber interface unit, the fifth channel inputs and outputs of which are connected to the third station inputs and outputs of the input unit by the automatic telephone connection lines, the output of the ShPS radio modem unit is connected to the input of the radio transmitter unit, the control input of which is connected to the control output of the unified interface controller, an additional output of the radio transmission unit the sensor is connected to the control input of the station’s self-test unit, the output of which through the radiation control unit is connected to an additional input of the antenna emitter, the third inputs and outputs of the station self-test unit are connected to the inputs and outputs of the radio, the first control inputs the outputs of the controller of unified interfaces are connected to the inputs and outputs of the antenna control system, the outputs of which are connected to the inputs of the slewing ring, the output of the block of the ShPS radio modem, through which the signal is transmitted For guidance and auto tracking of the antenna, it is connected to the control input of the antenna control system, the second control inputs and outputs of the controller of unified interfaces are connected to the inputs and outputs of the power amplifier.

A comparative analysis with the prototype shows that the claimed satellite subscriber station is characterized by the presence of new units: a bandpass filter, a broadband signal modem (SHPS) unit, a unified interface controller, a channel on demand controller (PST) unit, a station control panel, and subscriber interface unit ( BAI), radiation control unit, station self-test station control unit, antenna control system, line input unit with lines connected to it for issuing (receiving) qi rovyh channels according to standard junction C 1-PL-BI, dispensing lines (receive) channels RS-232 and junction lines for dispensing (receiving) channel automatic telephone and changes connections between the known circuit elements.

Thus, the claimed subscriber station satellite communications meets the criteria of the invention of "novelty."

Comparison of the proposed solution with other technical solutions shows that the introduction of new blocks and changes in connections with the rest of the circuit elements contributes to the manifestation of new properties of a satellite communications subscriber station, leads to increased noise immunity of communication channels, the station's bandwidth and to provide flexibility in organizing communications using such stations and expand functionality by ensuring the operation of the proposed subscriber station in various communication networks with different systems m access station with code and frequency-code separation of channels.

This allows us to conclude that the technical solution meets the criterion of "significant differences".

Figure 1 shows the structural diagram of the subscriber station of satellite communications, figure 2 shows the structural diagram of the block of the radio modem broadband signals (SHPS), figure 3 shows the block diagram of the controller providing channels on demand (FCT) and the control panel of the station, and in Fig. .4 shows a block diagram of a block of user interfaces (BAI).

The satellite communications subscriber station (Fig. 1) comprises an antenna 1, a bandpass filter 2, a low-noise amplifier 3, a radio receiver 4, a broadband signal (SPS) radio modem unit 5, a unified interface controller 6, an on-demand channel controller (PCT) 7, a remote control control (PU) station 8, a block of user interfaces (BAI) 9, a block of a radio transmitter 10, a power amplifier 11, a unit for checking the station’s self-operation 12, a radiation monitoring unit 13, an antenna control system 14, a rotary support device 15, a block 16 input lines, l line 17 for issuing (receiving) digital channels at a standard interface according to GOST 27232-87 (for example, at a standard interface C1-FL-BI), line 18 for issuing (receiving) channels at the RS-232 interface and line 19 for issuing (receiving) ) channels of automatic telephone communication.

The radio modem unit 5 of the broadband signals (Fig. 2) contains a reference frequency driver (FOC) 20, an analog-to-digital quadrature frequency converter 21 (ADC), a digital correlator 22, a synchronization search and detection device 23, a memory unit 24, the first 25 Viterbi decoder ( DKV), the second 26 Viterbi decoder, two-channel demodulator 27 broadband signals (SHPS), decoder 28 relative phase telegraphy (OFT), shaper 29 of the antenna guidance signals and antenna auto-tracking signals, information exchange unit 30, encoder 31 relative hydrochloric Phase Telegraphy (OBT), dual channel modulator 32 spread spectrum signals (NLS), 33 driver call pseudorandom sequences, and the general synchronization rebound (SRP VO / OS) driver 34 traffic channel pseudorandom sequences (PRS SP).

The on-demand channel controller (FCT) 7 (FIG. 3) comprises bus drivers 35, a communication controller 36 with a radio modem unit, a CAN control channel controller 37 and a microprocessor 38, and a station control panel 8 includes a TTL level interface converter 39 to the RS- interface 232, microcontroller 40, indicator 41 (display board or display) and numeric keypad 42.

Block 9 subscriber interfaces (BAI) (figure 4) contains a PIC processor 43, an ADSP processor 44, a flash memory unit 45, a programmable interface converter 46, an interface 47 for a standard interface for digital channels, an interface 48 for an RS-232 interface, an interface 49 for automatic channel interface telephone communications (PBX), vocoder 50 and codec 51.

The output of the antenna 1 through a band-pass filter 2 is connected to the input of a low-noise amplifier (LNA) 3, the output of which is connected to the microwave input of the radio receiver 4. The output of the radio receiver 4 is connected to the input of the block 5 of the radio modem of broadband signals (SHPS), to which the second signals are received from the output of the radio receiver 4 intermediate frequency (IF-2) receiving 70 MHz. The inputs and outputs of the block 5 of the ШПС radio modem are connected to the first inputs and outputs of the controller 6 of unified interfaces (KUI), the second inputs and outputs of which are connected to the first inputs and outputs of the unit 7 of the on-demand channel controller (FCT) to the consumer via a high-speed RS-485 interface, the second inputs and outputs of which, through the RS-232 interface, are connected to the inputs and outputs of the control panel of the 8th station.

One output of block 5 of the ShPS radio modem, through which a 10 MHz frequency signal of the reference reception generator is transmitted, is connected to the control input of the radio receiver 4.

The control output of block 5 of the ShPS radio modem, through which the guidance and auto-tracking signals of antenna 1 are transmitted, is connected to the input of the control system 14 of antenna 1.

The third inputs and outputs of the PCT controller unit 7 are connected to the third inputs and outputs of the controller 6 of the unified interfaces, the fourth inputs and outputs of which are connected to the first inputs and outputs of the station self-test unit 12, the second inputs and outputs of which via the CAN interface are connected to the fourth inputs and outputs of block 7 of the FCT controller. The fifth inputs and outputs of the FCT controller unit 7 through a serial port are connected to the first inputs and outputs of the subscriber interface unit 9 (BAI), the second inputs and outputs of which via the CAN interface are connected to the sixth inputs and outputs of the FCT controller unit 7.

The third inputs / outputs (digital channel inputs and outputs) of the subscriber interface unit 9 are connected via a standard interface to the first station inputs and outputs of the line input unit 16, the second station inputs and outputs of which are connected via the RS-232 interface to the fourth inputs and outputs of the subscriber unit 9 interfaces, fifth inputs and outputs (inputs and outputs of automatic telephone communication channels) which are connected to the third station inputs and outputs of the line input unit 16.

The second output of the block 5 of the ШПС radio modem, through which the signal of the second intermediate frequency of 70 MHz transmission is transmitted, is connected to the input of the block of the radio transmitter 10, the control input of which is connected to the control output of the controller 6 unified interfaces. The output of the block 10 of the radio transmitter is connected to the input of the power amplifier 11, the output of which is connected to the input of the antenna 1.

An additional output of the radio transmitter unit 10 is connected to the input of the station self-test unit 12, the output of which through the radiation monitoring unit 13 is connected to an additional input of the antenna 1.

The first control inputs and outputs of the controller 6 unified interfaces are connected to the inputs and outputs of the control system 14 of the antenna 1, the outputs of which are connected to the inputs of the slewing ring 15. The third inputs and outputs of the station self-test unit 12 are connected to the inputs and outputs of the radio 4, and the second control inputs and outputs of the controller 6 of the unified interfaces are connected to the inputs and outputs of the power amplifier 11.

The first, second and third linear inputs and outputs of the line input unit 16 are connected respectively to the line 17 for issuing (receiving) digital channels at a standard interface, line 18 for issuing (receiving) channels at the RS-232 interface and line 19 for issuing (receiving) channels of automatic telephone communications.

The inputs and outputs of the reference frequency driver (FOC) 20 of the radio modem unit 5 of the broadband signals are connected to the first inputs and outputs of the analog-to-digital quadrature frequency converter 21 (ADCS), the second inputs and outputs of which are connected to the first inputs and outputs of the digital correlator 22, the second inputs are the outputs of which are connected to the first inputs and outputs of the synchronization search and detection device 23. The second inputs and outputs of the synchronization search and detection device through the memory block 24 are connected to the third inputs and outputs of the digital relator 22, first and second data inputs-outputs of which are connected to data inputs-outputs of respectively the first 25 and second Viterbi decoders 26 (DHQ). The third and fourth inputs and outputs of the synchronization search and detection device 23 are connected to the input-outputs of the first 25 and second 26 Viterbi decoders, and the second input-output of the second 26 Viterbi decoder is connected to the first input-output of the relative phase telegraphy (OFT) decoder 28, the second input-output of which is connected to the information input-output of the two-channel demodulator ШПС 27, the first and second control inputs of which are connected to the control outputs of the first 25 and second 26 Viterbi decoders, respectively. The inputs and outputs of the common synchronization channel of the two-channel demodulator 27 broadband signals are connected to the inputs and outputs of the interface exchange unit 30, the information input-output of which is connected to the second input-output of the first 25 Viterbi decoder. The fifth input-output of the synchronization search and detection device 23 is connected to the input-output of the shaper pseudo-random call and hang-up sequences 33 (PSP VO / OS), the control output of which is connected to the first control input of the two-channel modulator 32 ШПС, the second control input of which is connected to the control output shaper 34 pseudorandom information sequences (PSP IR), the input-output of which is connected to the sixth input-output of the search and synchronization detection device 23. The output of the shaper 29 signals fishing antenna pointing and automatic tracking of the antenna is connected to the input of a two-channel demodulator 27 of wideband signals (NLS), and a third input-output of the second Viterbi decoder 26 is connected to the input-output of the encoder 31 OFT, whose output is connected to the input of a two-channel modulator 32 NLS. In this case, the input of the reference frequency driver 20 is the input of the block 5 of the broadband signal radio modem, the inputs and outputs of which are the inputs and outputs of the antenna pointing signal generator 29 and the antenna auto-tracking unit 30 and the interface exchange unit 30, the output of the two-channel SHPS 32 modulator is the output of the broadband signal radio block 5, the control output of which is the output of the driver 20 of the reference frequency.

The inputs and outputs of the bus formers 35 block of the controller 7 provide channels on demand (FCT) at the inputs and outputs are connected to the first inputs and outputs of the controller 36 exchange with the radio modem unit. The second inputs and outputs of the exchange controller 36 are connected to the first inputs and outputs of the controller 37 of the CAN control channel and connected to the first inputs and outputs of the microprocessor 38, the second inputs and outputs of which are inputs and outputs of the channel provisioning controller unit 7 on demand and through the RS-232 interface connected to the second inputs and outputs of the converter 39 of the TTL level junction to the RS-232 junction of the control station 8 station. In this case, the input-output of the bus drivers 35 is the first input-output of the on-demand controller unit 7, the second inputs and outputs of which are the second inputs and outputs of the microprocessor 38, the third inputs and outputs of which are the third inputs and outputs of the channel provision controller 7 a requirement whose fourth inputs and outputs are the inputs and outputs of the CAN interface of the CAN 37 controller.

The first inputs and outputs of the transformer 39 of the TTL level joint to the RS-232 joint are connected to the first inputs and outputs of the microcontroller 40, the second inputs and outputs of which are connected to the inputs and outputs of the digital keyboard 42, and the control inputs and outputs of the microcontroller 40 are connected to the control inputs and outputs indicator 41 (indication board or display). In this case, the second inputs and outputs of the converter 39 of the RS-232 interface to the TTL level are inputs and outputs at the RS-232 interface of the station control panel 8.

The PIC input of the processor 43 of the subscriber interface unit 9 (Fig. 4) is connected to the output of the programmable interface converter 46, the input of which is connected to the ADSP output of the processor 44, the first input-output of which is connected via the parallel port to the PIC input-output of the processor 43. The second input the ADSP output of the processor 44 via the address bus is connected to the first input-output of the flash memory unit 45, the second input-output of which is connected via the data bus to the third input-output of the ADSP of the processor 44. The fourth input-output via the address bus and the fifth input the output via the data bus of the ADSP of the processor 44 is connected respectively to the first and second inputs and outputs of the programmable converter 46 of the joint, and the sixth input-output of the ADSP of the processor 44 is connected via a serial port to the first input-output of the vocoder 50. The third input-output of the programmable converter 46 of the joint by the standard interface of digital channels in the TTL level is connected to the first input-output of the interface module 47 standard interface of digital channels, the fourth input-output of a programmable converter 46 joint and through the RS-232 interface, the TTL is connected to the first input-output of the RS-232 interface 48, whose control input at the RS-232 interface is connected to the output of the programmable interface converter 46, the signal input of which is connected to the RS-232 interface by the output of the RS interface module 48 -232. The second signal output “Subscriber mode” / “PBX” of the programmable converter 46 is connected to the signal input of the module 49 of the PBX channel interface, the first control input of which is “PBX mode control” which is connected to the second control output of the programmable converter 46 of the joint, the third control output is “Control the “Subscriber” mode of which is connected to the second control input of the PBX channel interface module 49, and the signal signal “Frame ready” of the vocoder 50 is connected to the second signal input of the programmable transform the interface 46, the signal output of which is connected to the input of the vocoder 50, the second input-output of which is connected via a serial port to the input-output of the codec 51, the input-output of the voice path of which is connected to the corresponding input-output of the module 49 of the ATC channel interface, while the second the inputs and outputs of the parallel port PIC of the processor 43 are the first inputs and outputs of the block 9 of the subscriber interfaces, the second inputs and outputs of which are the inputs and outputs CAN TTL PIC of the processor 43, the third, fourth and fifth inputs and outputs subscriber interface unit 9 are respectively the second input-output interface standard digital channel interface unit 47, the second input-output module 48 RS-232 interface and the input-output channel unit 49 PBX interface.

Antenna 1 consists of a mirror having a diameter of 1.2 m and an irradiating system.

Bandpass filter 2 is designed to protect the receiving path of the station from the microwave signals of its transmitter.

Low-noise amplifier 3, built according to well-known modern technologies, is designed to isolate and pre-amplify the received microwave signal. As such a block, a parametric amplifier with noiseless conversion of vibrational energy of a certain frequency can also be used.

The radio 4 includes a tunable band-pass filter for separating the signals of individual RF trunks, converters and amplifiers of intermediate frequency.

Block 5 of the radio modem of broadband signals (SHPS) is the base unit of the station and provides the implementation of the principles of a multiple access system based on the synchronous method of code separation of channels in the repeater. It includes a reference frequency driver (FOC) 20, an analog-to-digital quadrature frequency converter 21 (ADCS), a correlator 22, a synchronization search and detection device 23, a memory unit 24, the first 25 Viterbi decoder (DKV), and the second 26 Viterbi decoder , a two-channel demodulator 27 broadband signals (SHPS), a relative phase telegraphy decoder (OFT) 28, an antenna pointing signal and antenna auto-tracking signal generator 29, an information exchange unit 30, an OFT encoder 31, a two-channel modulator 32 wideband signals (SHPS), 33 ormirovatel call pseudorandom sequences, and the general synchronization rebound (SRP VO / OS), 34 driver information pseudorandom sequences (PRS SP).

The operation of block 5 of the radio signal modem of the BSC signal is as follows.

The input analog broadband signal from radio 4 at a second intermediate frequency of 70 MHz is fed to a radio frequency processing device (URO), built on the principle of analog-to-digital quadrature conversion (ASCP), and is used to convert the input RF signal to digital form, necessary for the digital correlator to work .

The RF processing device consists of a reference frequency driver (FOC) 20 and an analog-to-digital quadrature frequency converter 21. Block 20 serves to generate two reference signals at a frequency of 70 MHz, shifted relative to each other by 90 °. One signal is used to form the clock frequency, the other to form the response frequency of block 21. The 10 MHz reference signal for the reference frequency driver (FOC) is external and is generated in the radio receiver 4.

The tasks of the converter 21 include the conversion of the SHPS signal into a digital signal, the in-phase component (I) and the quadrature component (Q), which are fed to the digital five-channel correlator 22. The analog-to-digital quadrature converter 21 consists of an input signal commutator, a bandpass filter, and two amplifier converters and two ADCs. The input switch is used to switch operating modes and control, in which the internal health monitoring of unit 5 of the ShPS radio modem is performed.

The synchronization search and detection device 23 together with the general synchronization pseudo-random sequence generator (GPS GPS) and the pseudo-random information sequence generator (GPS GPS) 34 provide the formation of reference signals of the pseudorandom sequences when searching and tracking the received signal by the digital correlator 22, search control, entry into synchronism and signal tracking in a five-channel version, the formation of reference signals of the sine and cosine components p sequences (FOS COS, FOS SIN) for the correlator 22, the formation of the sine and cosine components of the pseudo-random sequences (pseudo-random information sequence PSP IP, having a single structure with a pseudo-random sequence synchronization network PSP _CC "pseudo-random sequence of the channel for general synchronization PSP OS, PSP subscriber station) management of search and entry into synchronism.

The block of the controller 7 providing channels on demand (FCT) contains bus formers 35, the controller 36 exchange with the block of the radios modem SHPS, the controller 37 of the CAN channel and the microprocessor PC 38.

Block 7 of the FCT controller of the specified composition is designed to provide docking in the FCT mode of digital streams of subscribers of secondary networks with the digital stream of the satellite channel. Block 7 of the FCT controller implements the following functions:

loads software modules;

performs a self-test of the PCT unit and the control panel of station 8, the interaction of software and hardware in the control channel of unit 5 of the ShPS radio modem;

accepts outgoing calls in the mode of providing a channel on demand from subscribers of secondary networks through block 9 BAI;

organizes and displays on the indicator of the control panel of the station 8 menu for adjusting the operational parameters of the station;

receives from the block 5 of the ShPS radio modem information of both the main and auxiliary channels and also their clock cycles;

transmits to the block BAI 9 information and clocks received from block 5 of the radio modem;

transmits to the block 5 of the ShPS radio modem information and clock cycles of the digital stream received from the BAI block 9;

accepts incoming calls (in the mode of providing a channel on demand) received in block 5 of the radio modem from the central station;

enables / disables the transmitter and adjusts the output level of the power amplifier;

generates address numbers of outgoing and incoming communications and transmits them to block 5 of the ShPS radio modem;

records and stores in a flash memory 38 of the control panel of the 8th station a directory of subscribers of the CDMA network;

connects the digital stream of the satellite communication channel of unit 5 of the radio modem, operating in the mode of providing the channel on demand, with the digital stream of the secondary networks.

The control panel of the station 8 in terms of functions relates to block 7 of the FCT controller. The main nodes of the control panel 8 are a PIC 39 microcontroller, a TTL / RS-232 interface converter 40, an indicator 41, and a numeric keypad 42. The front panel of the control panel 8 has a four-line indicator.

In addition, in block 7 of the FCT controller there are functions that allow you to transfer one of the three subscriber channels of the secondary networks to the radio channel with the priority assigned to them and interact with the BAI 9 through the CAN interface.

Block 9 subscriber interfaces (BAI) is used as a digital device for interfacing physical joints of terminal equipment of secondary networks with the satellite channel of block 5 of the ShPS radio modem in the mode of providing the channel on demand.

To ensure pairing, the BAI 9 unit includes the following nodes:

interface module with RPU, providing voice exchange of the PBX subscriber with vocoder voice transmission at a speed of 2.4; 4.8; 9.6 kbit / s;

RS-232 data transmission interface with a data transfer rate of up to 19.2 kbit / s, to which an external personal electronic computer (PC) or Hayes compatible modem is connected;

C1-FL-BI interface digital channel interface for duplex telephony;

PIC processor supporting interaction with the PCT controller unit 7 through a parallel LPT interface or a serial CAN interface;

ADSP processor with flash memory, providing programmatic work of a programmable interface converter for processing subscriber digital signals.

Block BAI 9 serves user interfaces independently of each other, that is, provides parallel service.

On the part of block 7 of the GOST controller, the maintenance is sequential. Block BAI 9 transmits and receives the digital stream one after another, that is, provides sequential service.

The main mode of the BAI 9 block is semi-automatic, priority service. First of all, service communication is provided, then duplex telephone (confidential) communication is organized, after it the TLF communication is serviced and, lastly, data (PD) is transmitted. The priority can be changed by commands from block 7 of the FCT controller.

The radio transmitter unit 10 is intended for the formation of a microwave signal with predetermined parameters and its amplification to the desired level. The radio transmitter unit 10 refers to the frequency-generating devices of the station, operates in a linear conversion mode and, in combination of parameters, provides signal coupling of the transmitting path to the block 5 of the radio signal modem of the NPS signal.

The 345/70 signal converter included in it converts the IF-1 (345 ± 5) MHz signal into an IF-2 signal with a frequency of 70 MHz. To do this, use the stand signal from 270 to 280 MHz in steps of 10 kHz. The stand formation scheme is based on the principle of digital automatic frequency adjustment of the generator with direct frequency division, and the 70/700 MHz signal converter performs the inverse conversion of the signal with a frequency of (70 ± 3) MHz into a signal with a frequency from 675 to 700 MHz.

The block of the shift generator of the test block 12 forms a frequency base Fopor = 600 MHz, with which the signal is transferred from the transmission range to the reception range. From the output of the block of the shear generator, the signal is fed to a control emitter to check the operation of the station in the "on itself" mode.

The control unit is carried out on an eight-bit data bus controller unified interface 6 from the control system of the station.

Block 12 to verify the station’s “work on itself” contains a range switch, a frequency shift generator, which provides the transfer of the spectrum of the transmission path to the frequency range of the receiver to organize a “loop” when checking the work of the station “on itself”.

The radiation monitoring unit 13 comprises a switch, an antenna equivalent, and a control emitter.

The antenna control system 14 comprises a manual antenna control unit, a controller, a switching and indication unit. It is designed to point the antenna at a repeater (RTR), placed on an artificial Earth satellite (AES) or spacecraft (SC), in manual mode and in auto tracking mode (AS).

Manual antenna pointing is performed using the tuning indicator for the maximum signal included in the station. After pointing the antenna to the maximum of the received signal from the RTR satellite in manual mode, the "Auto tracking" mode is activated. The “Auto tracking” mode is carried out jointly with the help of the control panel of the 8th station, block 7 of the FCT controller and the antenna control system 14. The necessary operation mode is set on the control panel of the 8th station.

The indicator of tuning to the maximum signal refers to digital devices and is intended for the initial pointing of the antenna of the subscriber station of satellite communication to the repeater (satellite). It is used at the initial stage of tuning the direction of the antenna of station 1. A digital signal in codes is received at the indicator input, which is then converted using an digital-to-analog converter (DAC) into an analog signal, which is then transmitted to the scale of a microammeter type M4248-0-100 μA-2, 5 V.

The controller is a standalone CAN controller of the antenna control system (SUA). Interaction with the PCT controller unit 7, which implements the main functions of the firmware in the station control system, is carried out through a three-wire serial CAN interface.

The controller controls the antenna 1 after the initial manual pointing of the antenna 1 using the tuning indicator for the maximum signal.

According to the antenna pointing signal (SNA) generated by the block 5 of the ШПС radio modem, the signal is digitally transmitted via the CAN controller of the block 7 of the FCT controller to the antenna control system controller and, using tracking systems in azimuth and elevation, automatically adjusts the antenna radiation pattern (LH) 1 in the direction that provides the maximum signal at the output of the block of the radio receiver 4, corresponding to the parameters E / No = 9 dB at Rosh≤10 ^-5 in the information band.

The controller of the SUA system unit transmits the word “AFU status” to the unit 7 of the FCT controller.

Along with the functions of the antenna control system (SUA), the SUA controller using the keyboard of the control panel of the 8th station turns the transmitter on and off in the block 10 of the radio transmitter of the station.

The transmitter is controlled as follows. Commands On Tx / Off The transmitters are transmitted to the AMS system controller via the CAN serial interface. In the controller, the serial code is converted to parallel and transmitted to the block of the switching and indication board, which executes commands through the control port of the microwave device, transmitting confirmation of the execution of the parallel code command in the parallel code. The AMS system controller again converts the signal into a serial code and, through the CAN interface, transfers it to block 7 of the FCT controller.

The interaction of the station operator with the control system of the station is carried out through the numeric keypad 42 (input commands) and the indicator 41 of the control panel 8 station, displaying the operating parameters of the station.

The main functions of the antenna control system are implemented in the AMS controller, developed on the basis of the M167-1C controller, which supports CAN communication.

The antenna is automatically tracked by the signal received by block 5 of the ShPS radio modem by the digital signal "Auto tracking", generated by the receiver of block 5 of the ShPS radio modem from the common synchronization channel (OS channel).

Since the block 5 of the ШПС radio modem interacts with the block 7 of the FCT controller through the controller 6 of the unified interface, the block 7 of the FCT controller, having received the signal via the RS-485 interface channel, transmits it via the CAN interface channel.

The main difference between the principles of building a control system for a station operating in a code-division multiple access system from the control system of existing satellite subscriber stations operating in a system with FDMA is as follows:

the organization of a communication session between the two proposed subscriber stations does not require the input of CWS containing a large number of parameters;

the process of organizing a duplex communication channel is carried out automatically from the moment a call is received from the terminal equipment via any of the subscriber interfaces.

Station control system programs are stored in the flash memory of the PCT controller unit, the ShPS radio modem unit, and the subscriber interface unit (BAI).

The rotary support device 15 for accurately pointing the antenna 1 to an artificial Earth satellite has an electric power drive, which includes an azimuth electromechanism and an elevation angle electromechanism.

The station provides procedures for establishing communication with the provision of channels on demand (FCT) between subscribers both in automatic mode (main mode) and in semi-automatic mode, through the station operator.

The procedures for establishing communication with PCT have a number of features, namely:

the station must establish a satellite link through the central station of the CDMA network. The point-to-point connection is not effective in this case, since the possibility of using a frequency resource based on code division of channels is used;

the procedure for establishing communication with the FCT requires for its implementation the service part of the message circulating in the secondary network: applications for the provision of a channel, subscriber or correspondent address, type of information transmitted, urgency category (priority), etc.

Thus, the switching and interface part of the station, providing data input / output, must provide the provision of channels on demand based on the implementation of internetworking protocols.

Networking is carried out at the physical level.

In the proposed subscriber station, multi-station access to a repeater (RTR), located on a spacecraft (SC), in a code-division multiplexing system, is based on block 5 of the ShPS radio modem of the signal, which is identified with the radio channel.

For the organization of interworking, block 7 of the on-demand channel controller (PCT) is used, which performs the following functions:

provides call and address signals from the block of user interfaces (BAI);

synchronizes packets of digital sequences, information signals arriving at the subscriber interfaces of the BAI unit from the terminal equipment of the communication node or the digital sequence of the satellite channel in the FCT mode and transmits information packets to the BAI unit;

carries out the information of the control channel of the central station of the satellite system with code division of channels through the call / end channel in time windows formed by the common synchronization channel “SOS”, “SOM”;

formation of packets of request or response information to the central station to provide a channel on demand: a subscriber’s call, a call receipt, a hang-up receipt;

interaction between the PCT controller block and the ShPS radio modem block is carried out through the unified interface controller (KUI);

interaction of the GOST controller unit with the subscriber interface unit (BAI) is carried out through the CAN interface;

control of input / output of information from the keyboard and indication with display on the four-line indicator of the type of connection, other service information.

The subscriber station satellite communications operates as follows.

The general operation algorithm of the proposed satellite subscriber station is as follows.

In the transmitting part of the subscriber station, the formation of the information broadband signal (BPS) emitted by the antenna as follows.

Information from the source of the message from any of the lines 17, 18 or 19 through the block 16 input lines, block 9 subscriber interfaces, block 7 of the controller providing channels on demand and the controller 6 of the unified interface is supplied to the modulator of block 5 of the radios SHPS. In block 5 of the radio modem, the signal is phase-shifted according to the law of the pseudo-random sequence generated by blocks 33 and 34. The generated BSS signal is amplified and transferred to the required frequency range in block 10 of the radio transmitter and transmitted through the antenna 1 to the relay through the antenna 1.

At the reception, the informational signaling frequency signal emitted from the repeater is received by the antenna 1 of the subscriber station and through the bandpass filter 2, a low-noise amplifier 3, the radio receiver 4 enters the receiving part of the block 5 of the radio signal modem. In the receiver of block 5 of the ShPS radio modem, correlation processing of the received signal is carried out using pseudorandom sequence generators (GPSS). The convoluted signal is demodulated and through the controller 6 of the unified interface, block 7 of the FCT controller, block 9 of the subscriber interfaces and block 16 of the input lines is received through one of the lines 17, 18 or 19 to the information recipient.

Network management is carried out by the central station, i.e. the network implements the principle of GOST with centralized management.

To organize a synchronous CDMA network, the central station begins to emit a general synchronization signal and detects it itself and synchronizes under it in frequency and delay.

After detecting the signal, the central station proceeds to receive request messages in the call / end (BO) channel emitted by subscriber stations synchronously to the common synchronization (OS) signal.

When entering the communication system, the subscriber station first searches for the OS signal in the ± 7.5 kHz band at the carrier frequency of 70 MHz by tuning the frequency of the 140 MHz synthesizer, common for the receiver and transmitter of the ShPS radio modem, in five gradations. After the detection of the OS signal, the measured offset of the OS signal relative to the natural signal at the clock frequency in the radio unit is entered with the opposite sign into the clock shaper of the radio transmitter unit to compensate for the existing mismatch, and the tracking mode for the clock cycles of the signal of the central station (CS) is activated. From the received signal, the OS of the PFP radio modem extracts a signal of a half-second frame - a time stamp (COM).

By the command “Transfer data to the VO channel”, which is received from the station control system, the ShPS radio modem unit turns on its transmitter and transmits its pseudo-random sequence (PSP) on board the repeater without superimposing information, and the radio receiver unit starts its search. When it detects its signal, the block of the ШПС radio modem switches to the correction mode of the carrier frequency of the transmitter for the received OS signal by changing the carrier transmission of the block of the ШПС radio modem.

After adjusting the carrier and clock frequency of the transmitter to the OS signal, the transmitter is synchronized in frames with the OS channel. To do this, on the pseudo-random sequence of the synchronization system (PSPS), the subscriber station starts transmitting every 0.5 s of the time stamp in the form of an n-element M-sequence (for example, n = 127 elements) (we get a 127-element M-sequence), it detects it and adjusts to the transmission so that it coincides with the time stamp of the channel on the OS in the receiver of the subscriber station. Then, in the window assigned to it, the subscriber station (AS), changing the PSPss to the PSP VO, transmits a request to the central station to provide a communication channel, while waiting in the OS channel for a receipt to receive the request to its address. If there is no call, it is repeated until a command from the station control system “Transmission of the information channel (IR)” or “Stop transmission in the VO channel” is received.

The information of the OS channel is analyzed by the control system and, depending on its content, generates commands for controlling the ShPS radio modem unit. Receiving a receipt by the CA on a signal OS for the admission request, and connection to the called subscriber, the station management system outputs a block radio PNS subscriber station command "Power transmission IR", on which on a pseudorandom sequence station timing (SRP _CC) superimposed information of the subscriber, taking this information from the called subscriber to his PSP, which is determined by the number of his address.

At the end of the subscriber-to-subscriber communication, the control system sends an “IR transmission shutdown” command to the ШПС radio modem unit, according to which the ШПС radio modem unit switches to transmission mode to the CCP _CC without information, replacing it at the moment of a fixed window on the CSP VO to transmit the end signal to the central station. Work in this mode continues until a command from the station control system “Stop transmission in the BO channel” is received.

When the station is operating for reception in the first frequency range (from 3440 to 3900 MHz) and the second frequency range (from 7900 to 8400 MHz), the signal received by antenna 1 through a band-pass filter 2, which protects the receive path from the signals of its transmitter, is fed to a low-noise amplifier 3 , from the output of the LNA 3, the amplified signal enters the radio receiver 4 for further processing.

Radio 4 performs filtering, converting the spectrum of the signals of the radio link down (from 3440 to 3900 MHz for the first band or from 7900 to 8400 MHz for the second frequency band) with compressing the spectrum into the intermediate frequency band IF-1 (345 ± 5) MHz, signal amplification, converting the received spectrum of signals to an intermediate frequency (IF-1), filtering and amplifying the intermediate frequency signal to the desired level.

The signal conversion in the radio 4 is carried out by the heterodyne method. A signal with a specific frequency band, for example 5 MHz or 10 MHz (the bandwidth of a system with code division multiplexing of CDMA channels allocated in trunks with direct relay by a spacecraft of an operating range from 7490 to 7540 MHz). Next, the amplified signal from the IF-1 frequency band equal to (345 ± 5) MHz is converted to the second intermediate frequency (IF-2) 70 MHz and fed to the input of unit 5 of the broadband signal (SHPS) radio modem.

The block of the radio modem 5 carries out the reception and processing of the signal strength signal according to the algorithm adopted for the modem with code division multiplexing.

Note that prior to the radio modem block 5, the receiving path of the proposed satellite subscriber station is single-channel.

The block of the radio modem 5 in the subscriber station organizes two channels: the call / end (VO) channel and the general synchronization channel (OS channel). A satellite communication subscriber station is connected via a call / disconnect (BO) channel to a common synchronization channel (OS channel) of a central station of a code division multiple access (CDMA) network.

The central station through the channel of general synchronization (OS) provides a connection (direct entry into communication on the allocated data) between two similar subscriber stations of satellite communications.

Duplex digital information channel (IR) between subscriber stations in the receiving mode depends on the type of information transmitted and operates at one of the speeds of 1.2; 2.4; 4.8; 9.6; 16.0 kbps and can be considered transparent.

In order to output information from the radio channel and transfer it to block 9 of the user interfaces (BAI), the simplex transparent channel is restructured. Block 5 of the radio modem generates clock pulses by which information is output to block 9 of the subscriber interfaces (BAI).

The BAI unit 9, using the clock frequency and clock pulses of the restructured channel, converts the digital information stream into information of the corresponding interface of the user interface, that is, the channel of the terminal equipment (OA) of the secondary network.

When the station is operating for transmission, the terminal equipment of the consumer through one of the lines 17, 18 or 19 for issuing (receiving) channels connected to the input unit of lines 16, and the corresponding interface of the subscriber interface unit sends a request for a satellite communication channel.

Block 9 BAI analyzes the request and sends it to block 7 of the FCT controller. Block 7 of the FCT controller according to the priority established in the satellite communications network of a code division multiple access (CDMA) system should present the communication channel to the subscriber with the highest priority. The remaining subscribers are not put up for service by the station. For this, block 9 BAI through the appropriate interface displays a message. The message code has the form CHANNEL BUSY.

Block 7 of the FCT controller generates an outbound communication request, which contains the address of the called station, and transmits a request for the provision of a satellite communication channel to block 5 of the ShNS radio modem for the function of code division of channels.

Block 5 of the radio modem generates an outgoing call for transmission on the call / end (VO) channel to the central (base) station of the CDMA network.

The outgoing call, formed by the block 5 of the ShPS radio modem, is a broadband signal of the pseudo-random sequence of the SRP IN. The center frequency of this spectrum is 70 MHz. The output signal for transmission of block 5 of the ShPS radio modem occupies a band of 6 MHz.

To transmit this signal, it must be moved to the transmission range. The transfer of the spectrum of the BSS signal from the central frequency of 70 MHz to the carrier frequency of the transmission is carried out in stages.

At the first stage, a transmission signal with a frequency of (70 ± 3) MHz is fed to the input of a radio transmitter unit 10, where, using a frequency synthesizer, it is converted into a signal in a frequency range from 675 to 700 MHz using a frequency synthesizer.

Thus, the output signal for transmission from 675 to 700 MHz of unit 5 of the radio modem is an input signal to the transmitting path.

Next, the signal of the BSS in the band from 675 to 700 MHz with a certain level is fed to the input of the mixer of the radio transmitter unit, to the other input of which frequency stands from the frequency synthesizer arrive.

Depending on the selected area in the frequency range of the spacecraft repeater, the spectrum of a high-frequency signal having a band of 6 MHz is transferred without changing the band to the frequency interval of the transmission range. Next, the signal is fed to the pre-amplifier of the block of the radio transmitter 10, which amplifies the signal also to a certain level, and from its output, the pre-amplified transmission signal is fed to the power amplifier 11.

The transmission signal in the 6 MHz band of the first (from 5725 to 6225 MHz) or second (from 7900 to 8400 MHz) frequency range from the output of the power amplifier 11 is fed to the input of the antenna 1.

A transmission information signal with an output power level is supplied to a power amplifier 11, which amplifies it and transmits it to the antenna 1. In the antenna, the signal is amplified and radiated by it.

It should be noted that the type of information transmitted and the information transfer rate affecting the energy of the radio link appear only during information exchange between similar subscriber stations of a satellite communication network mdcr.

When a connection is established between these stations, the power of the radio line corresponds to a transmission rate of 4.8 kbps.

To equalize the energy in the transmission path, the output power of the station is adjusted. The adjustment of the output power level 11 is carried out at the input of the power amplifier.

The sequence of operations performed by block 5 of the radio modem of the NPS signals to enter synchronism when installing a duplex channel with the called station is as follows.

Since the station is a subscriber in a radial satellite communication network, which is a synchronous system, the code division of subscriber stations in the central station of the network is carried out by temporarily shifting the pseudorandom sequence (SRP) of each subscriber station relative to the SRP channel of the general synchronization. In this case, the bandwidth in each subsequent channel is shifted 90 ° relative to the previous bandwidth and, in principle, the structure of the bandwidth of the general synchronization channel can be used to form the bandwidth of subscriber stations.

After the subscriber station is turned on, the block 5 of the ShPS radio modem receives signals at a second intermediate frequency of 70 MHz transmitted by the central station in the control channel (common synchronization channel) and adjusts its own synchronization system for the carrier, clocks, and cycles.

The subscriber station can proceed to the transmission of information to the central station, for which purpose the PSP structure of this station is formed, containing the numbers of the calling and called stations in the CDMA network. Transmission is via a call / end channel (BO).

The call / end signal from the subscriber station is fed to the radio station signal block of the central station BSS signals synchronously with the common synchronization signal, so there is no need to search for it. Carriers from different subscriber stations come on the same carrier, but in different phases (signals are orthogonal). Each frame of the transmitted information has a guard interval at which the carrier did not manipulate.

The moment of capture by the FAL ring of the demodulator of the non-manipulated carrier frequency completes the phasing of the frequencies of the transmitter and receiver of the radio modem.

To establish duplex communication between two subscriber stations, the central station (DS) also establishes a duplex channel with the called station through the control channel. Then it provides a channel in a free window of the call / end channel (BO) for the exchange of receipts on the establishment of a connection between the calling and called stations.

The flexibility of using network resources is manifested in the fact that during the connection, the subscriber station occupies the temporary windows of the BO channel only for the time the channel is provided. If the station does not transmit information, then the channel is busy with the communication schedule of other subscriber stations.

In the duplex communication mode between subscriber stations, the central station regulates the load of the satellite channel operating in the direct relay mode, transmitting commands to the subscriber stations to adjust the radiation power. When working in a CDMA network, the proposed subscriber station, through software and hardware, automatically adjusts the radiated power through the channel CS-ARU PRD.

Constant updating of connections is carried out in real time and is fully automated.

Exchange of voice information during vocoder voice transmission in automatic telephone mode “TLF-ATS”.

The main functions of the two-wire SLIC interface integrated into the vocoder:

in case of an outgoing call - determine the moment of picking up the handset and give the subscriber a signal (tone) of dialing permission of the called subscriber station;

to receive the number of the called subscriber station of the satellite communications network from the subscriber of the telephone exchange and broadcast it to the PCT controller unit 7 for transmission on the call / hang up channel of the ShPS radio modem unit to the central station.

Long and short beeps of telephones connected to the station characterize the call progress of a CDMA network subscriber.

In the process of establishing communication, this interface of the BAI 9 unit must receive a tone, a long beep, a short beep, dial the telephone number of the telephone exchange of the subscriber station and convert it into a digital stream for transmission to the PCT controller unit, which transmits it in the format received for transmission to the control channel block of the ShPS radio modem, that is, to the call / hang up (BO) channel together with their clock cycles.

The conversation interval between correspondents during vocoder voice transmission at speeds of 2400, 4800 and 9600 bps should be approximately 3 minutes (optimal from the point of view of the parameters of the communication schedule organized by the subscriber station).

Control of station parameters is carried out automatically and combined with information exchange.

To quickly display the current status of the equipment of the subscriber station, a display line and eight indicators on block 7 of the FCT controller are used. In this case, when the power amplifier is running, the “UM” indicator lights up. If the power amplifier is turned on and normal, then the “UM” indicator will glow continuously in the presence of a communication channel. If the amplifier is not normal or there is no communication channel, then the “UM” indicator will blink.

When the station is operating "on itself" and the "loopback" mode is activated, the LINE indicator lights up, and the "App. norm ”lights up if there is not a single signal of a malfunction from all devices of the station interrogated by the GOST controller unit.

When a subscriber station receives an incoming call, the “In. call ”, and when the operator establishes an outgoing connection, the indicator“ Out. call".

The technical efficiency of the proposed satellite subscriber station is to provide the required noise immunity, reliability, station throughput, flexibility and efficiency of communication in multi-station access networks with a synchronous code division multiple access channel on demand mode while ensuring the operation of various types of data terminal equipment with the required priorities.

Moreover, increasing the reliability of the station is due to the fact that in the proposed subscriber station, information is transmitted using broadband signals, thereby reducing the power spectral density of the emitted and received signals. This leads to improved electromagnetic compatibility and reduced influence of its transmitter on the receiving path of the station due to the inclusion of a band-pass filter in the receiving path, as well as compensation for narrow-band interference. The result is the required noise immunity of the radio line and the reliability of the subscriber station.

The increase in throughput is achieved through the implementation of synchronous code compression, GOST mode with centralized control from the CA. In this case, a prerequisite for the operation of the speakers in the network is to obtain permission to work from the CA (registration of speakers in the network, similar to receiving a SIM card or password).

In addition, the subscriber station uses a permanent monitoring and signaling system about all the processes of establishing a connection and negotiating (transmitting information), signaling the inclusion of equipment or a terminal device in a particular communication channel and its operating modes, which channel and in which mode communication, what type of communication is provided at a given time.

Improving the energy of the radio link is achieved by improving the signal-to-noise ratio when receiving on small antennas and using broadband signals.

In the present invention, the expansion of functionality has also been achieved by ensuring the operation of a subscriber station in various communication networks with different multiple access systems with code and frequency-code division of channels.

Samples of the proposed satellite subscriber station were manufactured, which passed state tests and showed reliable operation. The test results confirmed the correctness of the technical solutions, their technical and economic effect. The time between failures of the station amounted to about 5,000 hours and increased by more than three times, and the throughput increased by at least two due to an increase in the transmission speed.

Information sources

1. SU, copyright certificate No. 1072274 class. HBB 7/185, 1984.

2. RU, patent No. 2117392 class. HBB 7/185, 1998.

3. Satellite Communications and Broadcasting: A Guide. - 3rd ed., Revised and add. / V.A. Bartenev, G.V. Bolotov, V.L. Bykov and others; Ed. L.Ya. Kantora. M .: Radio and communications, 1997, fig. 15.1 p. 419 (prototype).

Claims (5)

1. A satellite communication subscriber station, comprising an antenna, the input of which is connected to the control output of the slewing ring device, a low-noise amplifier and a radio receiver connected in series, a radio transmitter unit and a power amplifier connected in series, the output of which is connected to the antenna input, characterized in that a band-pass filter that protects the input of the reception path from the microwave signals of its transmitter, a radio modem unit of broadband signals (SHPS), a unified controller interface, on-demand channel controller (PCT), station control panel, station self-test station, radiation control unit, antenna control system, subscriber interface unit, line input unit with lines connected to it for delivery (reception ) digital channels at a standard interface, lines for issuing (receiving) channels at the RS-232 interface and lines for issuing (receiving) channels of automatic telephone communications, the antenna output through a band-pass filter connected to the input of a low-noise amplifier I, the output of the radio is connected to the input of the broadband signal modem unit, the inputs and outputs of which are connected to the first inputs and outputs of the unified interface controller, the second inputs and outputs of which are connected via the RS-485 high-speed interface to the first inputs and outputs of the PCT controller, the second inputs are the outputs of which at the RS-232 interface are connected to the inputs and outputs of the station control panel, the third inputs and outputs of the PCT controller unit are connected to the third inputs and outputs of the unified interface controller, fourth e inputs and outputs of which are connected to the first inputs and outputs of the station operation check block, “second”, the second inputs and outputs of which are connected to the fourth inputs and outputs of the PCT controller unit, whose fifth inputs and outputs are connected via the parallel port to the first inputs and outputs of the unit subscriber interfaces, the second inputs and outputs of which at the TTL CAN interface are connected to the sixth inputs and outputs of the PCT controller unit, the third inputs and outputs of digital channels are connected to the first stations via the standard interface of the subscriber unit line inputs and outputs of the line input unit, the second station inputs and outputs of which at the RS-232 interface are connected to the fourth inputs and outputs of the subscriber interface unit, the fifth channel inputs and outputs of which are connected to the third station inputs and outputs of the line input unit by the automatic telephone connection , the output of the ShPS radio modem unit is connected to the input of the radio transmitter unit, the control input of which is connected to the control output of the unified interface controller, the additional output of the soya radio transmitter unit dinan with the control input of the station’s self-checking unit, the output of which through the radiation monitoring unit is connected to an additional input of the antenna emitter, the third inputs and outputs of the station’s self-checking unit of the station are connected to the inputs and outputs of the radio receiver, the first control inputs and outputs unified interface controller connected to the inputs and outputs of the antenna control system, the outputs of which are connected to the inputs of the rotary support device, the output of the radios modem block, through which the signals are transmitted antenna and auto tracking, connected to the control input of the antenna control system, the second control inputs and outputs of the controller of unified interfaces are connected to the inputs and outputs of the power amplifier. 2. The subscriber station according to claim 1, characterized in that the radio modem unit of the broadband signals comprises a reference frequency driver, an analog-to-digital quadrature frequency converter, a digital correlator and a synchronization search and detection device connected in series, and also contains a memory unit, the first Viterbi decoder, the second Viterbi decoder, a two-channel broadband signal demodulator, a relative phase telegraphy decoder (OFT), an antenna pointing signal generator and auto tracking I have antennas, an information exchange node, a relative phase telegraphy (OFT) encoder, a two-channel broadband signal modulator, a pseudorandom sequence of call, end and general synchronizer, a pseudorandom information sequence generator, and the third inputs-outputs of the digital correlator are connected to the second inputs the outputs of the synchronization search and detection device, the third and fourth inputs and outputs of which are connected to the inputs and outputs of the first and of the Viterbi decoders, and the first and second information inputs and outputs of the digital correlator are connected to the information inputs and outputs of the first and second Viterbi decoders, the second input-output of the second Viterbi decoder is connected to the input-output of the OFT decoder, the second input-output of which is connected to the information the input-output of a two-channel ShPS demodulator, the first and second control inputs of which are connected to the control outputs of the first and second Viterbi decoders, respectively, the inputs and outputs of the common synchronization channel the two-channel broadband signal demodulator is connected to the inputs and outputs of the interface exchange node, the information input-output of which is connected to the second input-output of the first Viterbi decoders, the fifth input-output of the synchronization search and detection device is connected to the input-output of the pseudo-random call and hang-up sequence generator, the control output of which is connected to the first control input of the two-channel ShPS modulator, the second control input of which is connected to the control output of of a pseudo-random information sequence, the input-output of which is connected to the sixth input-output of the synchronization search and detection device, the output of the antenna pointing signal generator and the antenna auto tracking is connected to the input of the two-channel BSS demodulator, the third input-output of the second Viterbi decoder is connected to the input of the OFT encoder, the output which is connected to the input of the two-channel ShPS modulator, while the input of the reference frequency driver is the input of the broadband signal modem unit, the inputs are Exit which are input-output driver signals and antenna pointing and automatic tracking antenna interface node exchange, yield NLS dual channel modulator is the output of block wideband radio signals, a control output which is the output of the reference frequency. 3. The subscriber station according to claim 1, characterized in that the on-demand channel controller (PCT) unit comprises bus drivers, an exchange controller with a ShPS radio modem unit, a CAN channel controller and a microprocessor, the input / output of the bus drivers being connected to the first input the output of the exchange controller with the block of the ShPS radio modem, the second input-output of which is connected to the input-output of the CAN channel controller and the first input-output of the microprocessor, while the input-output of the bus drivers is the first input-output of the roller DAMA, second input-output of which is the second input-output of the microprocessor, the third inputs-outputs of which are the third inputs-outputs of the channels of the controller unit on demand, fourth inputs-outputs of which are inputs and outputs CAN controller CAN-interface. 4. The subscriber station according to claim 1, characterized in that the station control panel comprises an RS-232 interface converter to the TTL level, a microcontroller, an indicator (indication board) and a numeric keypad, the first inputs and outputs of the interface converter to the TTL level being connected to the first inputs and outputs of the microcontroller, the control outputs of which are connected to the inputs of the indicator (display panel), the second inputs and outputs of the microcontroller are connected to the inputs and outputs of the digital keyboard, while the second inputs and outputs of the RS-232 interface converter at Low TTLs are inputs and outputs at the junction of the RS-232 station control panel. 5. The subscriber station according to claim 1, characterized in that the subscriber interface unit comprises a PIC processor, an ADSP processor, a flash memory unit, a programmable interface converter, a digital channel interface of a standard interface, an RS-232 interface, an automatic telephone communication channel interface interface, vocoder and codec, the input of the processor PIC connected to the output of the programmable interface converter, the input of which is connected to the ADSP output of the processor, the first input-output of which is connected via the parallel port to the input-output of the PIC process sora, the second input-output of the ADSP processor via the address bus is connected to the first input-output of the flash memory block, the second input-output of which is connected via the data bus to the third input-output of the ADSP processor, the fourth input-output via the address bus and the fifth input-output through a data bus which is connected respectively to the first and second inputs and outputs of the programmable interface converter, the sixth input-output of the ADSP processor via a serial port is connected to the first input-output of the vocoder, the third input-output One programmable interface converter is connected to the first input-output of the standard interface of digital channels via a standard interface of digital channels in the TTL level, the fourth input-output of a programmable interface converter is connected to the first input-output of the RS-232 interface through the RS-232 interface TTL, control input at the RS-232 interface of which is connected to the output of the programmable interface converter, the signal input at the RS-232 interface of which is connected to the output of the RS-232 interface, the second signal output is “Subscriber mode” / “ATS” the programmable interface converter is connected to the signal input of the PBX channel interface, the first control input of which is the “PBX mode control” which is connected to the second control output of the programmable interface converter, the third control output of the “Subscriber mode” which is connected to the second control input of the PBX channel interface, signal output The “frame readiness" of the vocoder is connected to the second signal input of the programmable joint transformer, the signal output of which is connected to the input of the vocoder, a second input-output of which via a serial port is connected to the input-output of the codec, the input-output of the voice path of which is connected to the corresponding input-output of the PBX channel interface, while the second inputs and outputs of the parallel port of the PIC processor are the first inputs and outputs of the subscriber interface unit, the second inputs and outputs of which are the CAN TTL PIC processor inputs and outputs, the third, fourth and fifth inputs and outputs of the subscriber interface unit are, respectively, the second inputs and outputs of the interface standard junction of digital channels, second inputs and outputs of the RS-232 interface and inputs and outputs of the PBX channel interface.

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